Waste Treatment in LCI
Letters to the Editor
Letters to the Editor: Comment and Reply Comment Waste Treatment in Product Specific Life Cycle Inventories Part I: "Incineration" by M a r k u s Kremer, Gertraud Goldhan and Michael Heyde, Int. J. LCA 3 (1) 47-55 (1998) Part II: "Sanitary Landfill" by Jiirgen Bez, Michael Heyde and Gertraud Goldhan, Int. J. LCA 3 (2) 100-105 (1998)
Stefanie Hellweg, Stephanie M 6 s s n e r Swiss Federal Institute of Technology Zurich, Chemical Engineering Department, Safety and Environmental Technology Group, ETH-Zentrum, Universitfitstr. 33, UNL, CH-8092 Zurich Corresponding author: Stefanie Hellweg, e-mail:
[email protected] In the 1998 isstles 1 and 2 of the International Journal of LCA the Fraunhofer Institute in Freising, Germany, published two articles concerning waste treatment in product specific Life Cycle Inventories (LCI). In the first paper the authors describe a model for the calculation of inventory data concerning an incineration plant (Kltl-:M~.l~et al., 1998). The seco,id paper refers to the disposal of waste in sanitary landfills (B~:z ct al., 1998). Both articles lack a literature review. Thus we will try to give an overview of existing models in this letter and compare them to the Fraunhofer model. We will restrict our comments to the first article (KRF;MI-;Ret al., 1998). As KItExll-:l~ et al. (1998) correctly point out in their introduction, many studies of the past exclude waste treatment in the inventory analysis due to a lack of a well functioning allocation model. Unfortunately it is not mentioned in the article that this gap was already discovered a few years ago, which led to the development of several waste treatment models in various countries. In this letter we want to outline four European models, which all allow a product specific assessment of waste treatment. In Germany, the ifeu Institute in Heidelberg developed a model for incineration, sanitary landfills, and waste water treatment back in 1994. The model was first used and described in a Life Cycle Assessment study of packaging materials (FsANKE et al., 1994). This incineration model considers the incineration process including a wet/semi-dry flue gas purification system, the landfilling of slag, the gathering as well as the transportation of waste. It also calculates the amounts of some ancillary inputs (i.e., Ca(OH), and water) but disregards the emissions and resource use resulting from their production. When calculating the waste input related emissions of the incineration, the ifeu-model distinguishes between waste types with different contents of inert substances. In 1996, the E T H Zurich in Switzerland also developed a model for incineration, sanitary landfills, and waste water treatment (ZJMMERMANNet al., 1996). This model was, for instance, used for the calculation of packaging inventory data (BUWAL, 1996), which are now part of the new Simapro Software. The incineration process (wet flue gas purification), landfilling of incineration residues, production of pro-
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tess materials, infrastructure, the gathering as well as the transportation of waste are part of the system boundaries. Recently the incineration model was renewed, now differentiating between transfer coefficients * for inert and burnable waste materials (Hl-I.i.Wl-:r 1998; Hl-:l.l_wE6et al., 1998). The software tools (Excel) and the report (Zlul.xlt'lt,~lANN et al., 1996) can be ordered by the public, providing a tool to calculate end-of-pipe inventory data. The T N O Institute in The Netherlands has published several articles dealing with the allocation of waste treatment models (e.g. E(;c;H.s and VANI)I':R VFN, 1994; EGGEI.Sand VAN OER VEN, 1995). Their model is briefly described in (Ui)o l)i~ HAES and VANHALEN, 1997), with a comprehensive publication being in progress. The TNO-model considers the incineration process (flue gas purification with closed water cycle) and the landfilling of incineration residues. Similar to the above-described models, T N O distinguishes between inert and burnable waste input fractions. Also in 1997, the Swedish Environmental Protection Agency published a report on solid waste treatment in LCA with reference to incineration and sanitary landfills (SuNDQVlSTet al., 1997; SUNDQVlST, 1998). The product related incineration emissions/outputs are calculated with factors based on linear relationships. Here, the landfill model for incineration residues makes a difference between the surveyable time period and the time period afterwards. In contrast to the Fraunhofer model (FRANKEet al., I994), all models outlined above consider the landfills for slag to be part of the system. However, the models vary much in regard to the time period under consideration and the sum of anticipated emissions. The range varies from considering the emissions within the first decades, as performed in the T N O model z, to indefinite time horizons (ZIMMERMANNet al., 1996; StONDQVZSTet al., 1997). The workshop "Systems Engineering Models for Waste Management" in G6teborg, Sweden (25 - 26/02/1998), pointed out that the long term behavior of landfills is a major issue. We fully agree with (actors representing the relationship betwgen waste input and emission/ residue output -' oral conversation with B. van der Yen, P. Eggels, and B. Rijpkema, Apeldoorn (NL), February 17, 1998
Int. J. LCA 3 (6) 302 - 304 (1998) 9 ecomed publishers, D-86899 Landsberg, Germany
Letters to the Editor
this point, as the life cycle approach should consider all emissions from cradle to grave. Subsequently it does not allow cutting off emissions after a certain time period in our opinion, Moreover, recent LCA studies showed that the impacts of the landfills for incineration residues outdo the impacts caused by the incineration process itself by far (HEI,LWEGet al., 1997) so that these landfill impacts should not be neglected. These results are maybe even underestimated, as the ETH model only considers the "predictable amount of emissions" d r a w n from availability tests whereas there are also advocates for considering all landfill components as future emissions L A u t h o r s from the area of substance flow analysis have already discovered the importance of landfill emissions in c o m p a r i s o n to air emissions a few years ago (BAccINI et al., 1993). As a consequence, we regard the non-mentioning of a landfill model for incineration residues in the Fraunhofer model to be a major deficit. There is c o m m o n agreement on basic allocation aspects like the differentiation between process and product related emissions. Process related emissions are independent from the waste input and will therefore be accounted to the overall waste. In c o n t r a s t to this, product related emissions are caused by certain input components of the waste. The assignment of emissions to either one of those two groups is fairly similar in all models. However, there are a few exceptions; e.g., the N O emissions which can be formed by several reaction paths (fuel N O : thermal oxidation, p r o m p t N O - f o r m a t i o n ) . In the different models they are either characterized as product dependent (Ui3o l+t+HAESand VANHAI.~:N, 1997), as process dependent (KI~.I:MERet al., 1998; FRANKEet al., 1994) or as a combination of both (ZIMMrRMANNet al., 1996; SUNDQVlST et al., 1997). In general, the regular temperatures in an incinerator do not reach the lower limit for thermal o x i d a t i o n except in some hot spots. Therefore we think that it is not justified to consider all N O emissions as process d e p e n d e n t as done in the Fraunhofer model. Concerning the product specific emissions no consensus has been reached yet on whether the relation of waste input and emission o u t p u t can be represented by constant transfer coefficients. Ifeu, T N O , and ETH consider a carefully applied adaptation of the transfer coefficients to be helpful for a better representation of the real happenings, whereas the Swedish and the Fraunhofer model work with linear relationships a n d thus do not differentiate between different waste input materials. In our opinion a distinction between inert and b u r n a b l e fractions of the waste should be taken into account. Otherwise the fact that inert waste is generally transferred to the slag is not included in the model, neglecting k n o w n causal relationships. KREMER et al. (1998) note that the transfer coefficients in their table 1 from the Wiirzburg MSW were "cross-checked with literature d a t a " , unfortunately they do not say which literature they used. We compared the coefficients with some of our literature data (BELEVI,1998; MORFet al., 1997; BELEVI, 1994; REIMANN et al., 1989; SCHNEIDER,1987), and did not find matching d a t a for some of the coefficients, e.g. the cox
3 E.g. oral statement of G. Finnveden(Dep.of SystemsEcology,Stockholm University, Sweden) on the workshop "System Engineering Models for Waste Management" in G6teborg, Sweden(25-26/02/1998)
Int. J. LCA 3 (6) 1998
Waste
Treatment
in LCI
efficient for Cd to grate ash (which is very high). Moreover, many substances are missing in Table 1 whereas others are not used in the calculation. With regard to the flue gas treatment, the Fraunhofer model considers the clean gas emissions as constant and allocates them to the flue gas volume. This approach is different from the approach used in the other models, which use transfer coefficients also for this part of the calculation. Certainly the reasoning of KREMER et al. (1998) is justified, as the clean flue gas emissions really do not vary much with the waste input. Like the other models, KI~EMERet al. (1998) allocate the energy production to the lower heating value of input substances. They propose a calculation from the elementary composition of the waste according to the formula of Bole. Although this procedure is theoretically correct, we would rather advise to take the heating value from the energy balance of the incineration plant by comparing the a m o u n t of produced steam to the a m o u n t of input waste. In Switzerland, the calculation of the heating value according to the formula of Bole would result in a heating value of 6.6 MJ/kg, whereas it is almost 11 MJ/kg in reality (I.I~M,\~.~, 1994). Values for single input materials are available from literature as well, e.g. see list in ZIMMrI~MANNet al. (1996). From the above mentioned points we conclude that the Fraunhofer model does not offer major improvements to already existing models, but shows somc major deficiencies instead. The main problem is the neglecting of the emissions resulting from the landfills of incineration residues, which outdo the emissions from incineration. 113 their introduction KI~i'MI-;Ret al. (1998) criticize that many LCA studies only list the a m o u n t of generated waste, but o13 the other hand they also only list the a m o u n t of produced incineration residues without considering the potential emissions (see Tables 6 and 7). In general, this procedure is only a small improvement in comparison to completely excluding impacts resulting from waste generation. The incineration model itself is not very well explained and does not show advantages to other existing models. Furthermore, the chosen literature is neither complete nor up to date. References BACCINI,P., GAMPER, B. (Eds.) (1993): Deponierung fester Rihckstiinde aus der Abfallwirtschaft. v/d/f, Zhrich BELEVI,H. (1998): Environmental Engineering of Municipal Solid Waste Incineration. Habitilation, Stoffhaushalt und Entsorgungstechnik, ETH Ziirich, Diibendorf BELEVl, H. (1994): Wie wird Schlacke erzeugt? In: EAWAG, Entwicklung und Umsetzung neuer Qualitkitsanforderungen in der Abfallwirtschaft. D~ibendorf, 14.-16/09/1994 BEZ,J., HEYDE,M., GOLDHAN,G. (1998): Waste Treatment in Product Specific Life Cycle Inventories; Part II: Sanitary Landfill. Int. J. LCA Vol. 3 (2): 100-105 BUWAL Bundesamt ffir Umwelt, Wald und Landschaft (1996): C)koinventare fiir Verpackungen. Schriftenreihe Umwelt No. 250, Bern EGGELS, P., VAN DER VEN, B. (1994): Allocation model in case of multiple waste handling. In: Huppes, G. and Schneider, E, European Workshop on Allocation in LCA. SETAC-Europe, Leiden (NL), 24-25/0211994 EGGELS,P., VANDEr VEN, B. (1995): Allocation model for Landfill. In: Finnveden, G. and Huppes, G., Life Cycle Assessment and
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Waste Treatment in LCI Treatment of Solid Waste. AFR No. 98, Swedish Environmental Protection Agency, Stockholm, 28-29/09/1995 FI~aNKE,A., Gm(;RICH,J., KNAVPe,E, KNOI~8, W., SCHORB,A., VieTZe, M. (1994): Okobilanz von Verpackungen. Endbericht No. 103 03 220/04, Institut fiir Energie und Umweltforschung Heidelberg GmbH, Heidelberg, 03/1994 HrLt.wl~c;, S. (1998): Allokation bet der Kehrichtverbrennung. In: Frischknecht, R. and Hellweg, S., Okobilanz-Allokationsmethoden; Unterlagen zum 7. Diskussionsforum Okobilanzen. Zurich (CH), 24/07/1998 HELtWEt;, S., BINt~Ll~,M., HUNGERBOHLER,K. (1998): Model for an environmental evaluation of waste treatment processes with the help of life cycle assessment. In: Sundberg, J., Systems engineering models for waste management, forthcoming, The Waste Research Council (AFN), G6teborg (Sweden), 25-26/02/1998 Hel I.wl~c;,S., WEIDENHAUIrr,A., HUNGERBOHI.ER,K. (1997): Life Cycle Assessment of Thermal Waste Processes in Switzerland. In: SETACEurope, 5th LCA Case Studies Symposium. Brussels, 2/12/1997 KI~I~MER,M., GOLI)HAN,G., HEYDe, M. (1998): Waste Treatment in Product Specific Life Cycle Inventoi'ies; Part I: Incineration. Int. J. LCA Vol. 3 (1): 47-55 LrMANN, M. ( 1994): Grundlagen der Abfalltechnik. Verlag C. Herrmann Consulting, Diibendorf
Letters to the Editor
MORF, L., Rn-rEr, E., BRt:X.~ER,P. H. (1997): G~ter- und Stoffbilanz der MVA Wels. Technische Universit/it Wien, Wien, 05/1997 REIMAXN,D.O. (1989): Miillverbrennungsschlacke- Inhaltsstoffe, Mengen, Verwertbarkeit. U W S F - Z. Umweltchem. Okotox. 2 : 18-25, 1989 SCHNEIt)rR,J. (1987): Bestimmung der elementaren M/illzusammensetzung durch Analytik der M~llverbrennungsri~ckst/inde. In: Thomd-Kosmiensk), K., Messen und Analysieren an Abfallverbrennungsanlagen. EF-Verlag SUNDQVIST,J.-O., F1NNVEDEN,G., STRII'PLE,H., ALBERTSSON,A.-C., KARLSSON,S., BERENDSON,J., HOGLUND,L.-O. (1997): Life Cycle Assessment and Solid Waste - Stage 2. AFR No. 173, Swedish Environmental Protection Agency, Stockholm SUNr)QVlST,J.-O. (1988): Life Cycle Assessment and Solid Waste; A guideline for handling waste disposal in LCA. Draft, Swedish Environmental Research Institute, Stockholm UI)o I)E HAES, H. A., vax HALEN, C . J . G . (Eds.) (1997): Results of the Dutch Platform LCA & Waste. Pi!MC, The Hague ZIMMERMANN,P., DOKA, G., HUBER,E, LAF,HARDT, A., MENARD,M. (1996): Okoinventare yon Entsorgungsprozessen, Grundlagen zur Integration der Entsorgung in Okobilanzen. ESU-Reihe No. 1/96, lnstitut fiJr Energietechnik, ETH Z[irich, Ziirich, 08/1996
Reply Markus Kremer, Gertraud Goldhan, Michael Heyde Frat, tahofer-lnstitut for Verfahrenstechnik und Verpackung, Giggenhauser Str. 35, D-85354 Freising; Germany; http://www.ivv.fhg.de We highly appreciate that the international discussion on our approach of material related modelling in the area of waste management is opened by the comments from S. Hri.t.w~x; and S. M(')~SNEI,, on our publication "Waste Treatment in Product Specific Life Cycle Inventories, Part h Incineration (Int..l. LCA 3 (1) 47-55 (1998)), Part It: Sanitary Landfill (Int. J. LCA 3 (2) 100-105 (1998))". These comments include a lot of suggestions which can be very useful for improving our process model. Nevertheless, we would like to reply on some points of criticism and misunderstanding contained in these comments. HEI.I.WEG and MOSSNEP.criticise that no former publication on the subject of our publication is discussed or mentioned. They refer to some other approaches of material related modelling in the area of waste management and indicate the corresponding literature. The approach of the ifeu Institute was developed by ifeu in a joint project of ifeu, GVM and our Institute in 1994. The deficits of this model approach were the incentive for the development of our own incineration model. The other approaches mentioned are described by workshop proceedings and reports which are unfortunately not available for us until now. Furthermore, most of the publications mentioned by HELLWEGand MOSSNERwere published after we had finished our publication, Part I of which on "Incineration" was submitted in March 1997. HELLWEG and MOSSNERcriticise that the further treatment of the slag from the waste incineration is not included in the model. With regard to this criticism, the goal of our approach - the materialrelated description of the effects of the waste incineration - has to be pointed out. Starting from this goal definition, the system boundaries for the calculation of the energy and material balance have to be defined. As shown in Figure 3 and 4, the slag is an output flow of the system studied and the treatment of the slag is located outside the system described by the model. For example, in the case of disposing the slag on a municipal landfill site, the environmental impacts resulting from the treatment of the slag could be calculated by the approach described in Part II on "Sanitary Landfill".
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Furthermore, the modelling of the formation of NO x in the furnace as exclusively depending on process parameters (temperature, air excess, etc.) is criticised. 7"his objection is justified but it is of minor relevance if we take the system boundaries into consideration. As an output value of our process model, the concentration of NO x in the clean gas (and not in the raw gas) is calculated, which is only process dependent, as the emissions in the clean gas after flue gas purification are assumed to be no longer depending on the input composition. This assumption has to he limited when looking at substances like HCI or SO_,. For these substances, it has to be checked whether the elements which cause their formation are contained in the fuel. If, e.g. no chlorine is contained in the specific fuel under consideration, no HCI emissions will be allocated to the incineration of this specific fuel. The allocation of slag to an ash-free input, as implied in the comments, is also impossible. The distribution of the incombustible fraction of the input to the output flows is calculated due to transfer coefficients as shown in Figure 5. The references have to be completed by the data sources we used for comparing the transfer coefficients derived from data measured at the Wuerzburg MSWL These data sources are included in the references [2] and [8]. With regard to the allocation of the energy produced in the waste incineration, it is suggested in the comments to compare the amount of steam produced to the amount of waste input. This approach does not answer the question which part of the steam produced can be allocated to a special waste fraction. This question is of major importance to the assessment of waste incineration in the context of product LCI and it can only be answered when the calorific value of the special waste under study is known. The calorific value has to be calculated by a theoretical approach if it is not known from experimental or literature sources. For the determination of the calorific value of solid fuels, the formula of BoIE is commonly used and the values calculated with this formula show a good correspondence to the measured values.
Int. J. LCA 3 (6) 1998